Health Food

ABSTRACT

The object of the present invention is to consume raw food cultivated in appropriate soil. 
     The constitution of the health food is: consuming cereals including rices and wheats with or without husk, millets, pulses, tubers, leaf vegetables, fruit vegetables, rosette crops, root vegetables, citrus fruits, fruits, melons, seaweeds, and liverworts etc. as is; or consuming powders thereof, or by soaking in water so as to process to a degree that cell are not destructed (or if cells are destructed, the whole of leaf vegetables including root, stem, and leaf or a portion thereof are consumed as e.g. juice) and consuming without processing treatment including heating, boiling in water, or steaming; or these cereals, millets, or pulses are soaked in water to allow sprouting, and consumed at around the time of sprouting without processing treatment including heating, boiling in water, or steaming.

TECHNICAL FIELD

The present invention relates to a health food which ameliorates diseaseof a body and builds a healthy body. Specifically, the invention relatesto a health food which builds a body that suppresses intractablediseases such as diabetes.

BACKGROUND ART

Conventionally, various products have been proposed as health food. Forexample, Japanese Patent No. 3019261 entitled “Raw Vegetable HealthFood” (Patent document 1) discloses a health food composed of acombination of raw vegetables and uncooked brown rice with addition ofcommon salt.

Further, in particular, diabetes which is considered an intractabledisease often induces complications such as arteriosclerotic angiopathy.It is therefore necessary in treatment of diabetes to maintain goodnutritional and health conditions and to acquire resistance againstvarious diseases. The following products have been recently proposed assuch health food.

For example, in Japanese Patent Application Laid-Open No. 2003-189803(Patent document 2), cooked rice is proposed in which a healthpharmaceutical having medicinal properties is applied onto the surfaceof brown rice, etc. to produce traditional medicinal rice, which iscooked by ordinary method. Further, in Japanese Patent ApplicationLaid-Open No. H09-40566 (Patent document 3), fermentation product oflactic acid bacteria obtained from a mixture of rice bran and powderedbrown rice is known. In Patent document 4, it is known to use brown ricegerm as a substrate, and this is mixed with reishi mushroom, the mixtureis heat-treated, inoculated, and then cultured.

-   Patent document 1: Japanese Patent No. 3019261, pp. 1-   Patent document 2: Japanese Patent Application Laid-Open No.    2003-189803, pp. 1-   Patent document 3: Japanese Patent Application Laid-Open No.    H09-40566, pp. 1-   Patent document 4: Japanese Patent Application Laid-Open No.    2002-29994, pp. 1

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention

Patent document 1 shows consuming of raw vegetable and brown ricegenerally cultivated in ordinary soil, but the nitrogen componentabsorbed from the soil cannot be ingested enough.

The traditional medicinal rice of Patent document 2 was made by applyinga health component onto the surface of brown rice etc., cooked, andconsumed, and processing of brown rice was troublesome. Further, Patentdocument 3 describes a product where fermentation product of lactic acidbacteria is added to rice such as brown rice, and relates toimmunoadjuvant. In addition, Patent document 4 shows processing of brownrice etc., in which brown rice etc. is steamed, this is inoculated andmixed together with e.g. reishi mushroom.

The present invention provides for improvement on conventionallyproblematic food such as cereals which have harmful effects on humanbody and for food that builds a healthy body.

In particular, the present invention provides for a health food with theprimary objective to consume without steaming or heating, and withoutprocessing treatment of the surface of, for example, cereals includingrice (brown rice, wet-field rice, dry-field rice, ancient rice, fragrantrice, etc.) and wheat (wheat, barley, oat, etc.); millets includingItalian millet, Chinese millet, buckwheat, Indian corn, Japanese millet,corn, and sweet corn; or pulses including sesame, soybean, black bean,adzuki bean, and kidney bean; tubers including sweet potato, potato,Jerusalem artichoke, black sweet potato, Chinese yam, Japanese taro,Japanese yam, and Caiapo; rosette crops; melons; fruit vegetables; rootvegetables; citrus fruits; and fruits.

Another object of the present invention is to provide for a health food,in which it is important that the health food is not digested andabsorbed in the small intestine, but rather digested in the smallintestine, degraded in the large intestine and absorbed into the body.

The object of the present invention is to provide for a health foodsuitable for the body, in particular suitable for diabetes, which do notgo through the process of heating or steaming of, for example, uncookedcereals, millets, and pulses, or these foods without husk.

Means for Solving the Problems

The present invention comprises the following constitution to achievethe above objects.

The constitution of the health food is: rices, cereals, millets, pulses,tubers, leaf vegetables, fruit vegetables, citrus fruits, melons,fruits, rosette crops, and root vegetables, or rices, cereals, millets,and pulses with or without husk are consumed as is; or dried or powderedproduct soaked in water, and consumed as a whole without processingtreatment including heating, boiling in water, and steaming, or dried,powdered, and consumed; or, for the cereals, millets, or pulses, soakedin water to allow sprouting, and consumed at around the time ofsprouting without processing treatment including heating, boiling inwater, or steaming.

The above described object of the present invention can be achieved by ahealth food comprising the constitution of consuming grains of thecereals, millets, pulses, tubers, fruit vegetables, leaf vegetables,seeds, citrus fruits, fruits, green vegetables, or root vegetables ofconsuming as is, or consuming powdered grain, in which one or more of 2to 3 kinds of these grains are consumed in a size suitable as food, butnot limited by size; or the constitution of consuming the cereals,millets, and pulses in beta-starch state, and allowing degradation bydigestive fluid within esophagus, stomach, and small intestine,fermentation and degradation by enteric bacteria within large intestine,and digestion and absorption.

In addition, the above described object of the present invention can beachieved by a health food in which cereals including rices and wheats ormillets with or without husk; pulses including sesame, soybean, blackbean, adzuki bean, and kidney bean; tubers including sweet potato,potato, Jerusalem artichoke, and black sweet potato; fruit vegetables;or root vegetables, are produced in a soil, in which agriculturalchemicals including insecticide, bactericide, and antibiotic orinorganic synthetic materials such as synthetic food, syntheticadditive, and chemical fertilizer remain in a small amount, essentiallydo not remain, in which fungi, microorganisms, and insects can coexistwith the food chain, and in which organic fertilizer that does not usee.g. the above described agricultural chemicals is added, and consumedas is, or consumed powders thereof or soaked in water, or consumed as awhole, or dried, powdered, and consumed; or, for the cereals, milletsand/or pulses, soaked in water and consumed when sprouted or at aroundthe time of sprouting.

The health food of the present invention is a great shift fromconventional views on food. In other words, it is a health food whichcan maintain health of the body to have resistance against pathogens bya small amount of food. Particularly, it is important that it isconsumed raw as is, digested in the small intestine, and degraded andabsorbed in the large intestine.

As used in the present invention, consuming as a whole means that incase of vegetables, consuming not just the leaf part, but the entiretyincluding the stem and root parts. For example, in case of eggplant, itmeans consuming the entirety of vine, stem, and fruit. By consuming theentirety, it is possible to ingest well-balanced nutrients.

The minimal condition is to produce and cultivate cereals, millets,pulses, tubers, citrus fruits, fruits, melons, leaf vegetables, fruitvegetables, and root vegetables etc. by its natural state in nature insoil without using any inorganic agricultural chemicals etc.

It is well known that consuming uncooked cereals, millets, and pulsesdirectly as grains results in chewing well in the mouth, leading tostrengthening of the jaw and activation of the brain. In addition, it issaid that in the case of cereals and millets at around the time ofsprouting, gamma-aminobutyric acid (GABA) increases to build a healthybody.

When the cereals, pulses, vegetables, citrus fruits, fruits, melons,leaf vegetables, fruit vegetables, and root vegetables etc. of thepresent invention cannot be consumed raw, it may be powdered andconsumed dispersed in water. In addition, it can be consumed delectablywhen it is made into cereal juice or soup, by mixing not just one butmultiple kinds of cereals.

Foods that can be used in the health food of the present invention are,but not limited to, many kinds of food including the above describedcereals including rices such as wet-field rice, dry-field rice, ancientwild rice, and fragrant rice, and wheats including wheat, barley, andoat; or millets including Italian millet, Chinese millet, buckwheat,Indian corn, and Japanese millet; or pulses including sesame, soybean,black bean, adzuki bean, and kidney bean; tubers including sweet potato,potato, Jerusalem artichoke, and black sweet potato; citrus fruits;fruits; melons; leaf vegetables; fruit vegetables; or root vegetables.

For example, the above described cereals including rices includingwet-field rice, dry-field rice, ancient wild rice, fragrant rice andwheats including as wheat, barley, and oat, with husk, and cerealswithout husk;

millets including Italian millet, Japanese millet, Chinese millet,buckwheat, Indian corn, corn, and sweet corn, or seeds including walnut;

pulses such as sesame, soybean, black bean, adzuki bean, kidney bean,green pea, and favabean;

tubers including sweet potato, potato, Jerusalem artichoke, Japanesetaro, Chinese yam, Japanese yam, Caiapo, and dasheen;

vegetables such as green onion, green perilla, perilla, green asparagus,parsley, wormwood, rapeseed, and cinnamon;

leaf vegetables such as qing-geng-cai, komatsuna, leek, spinach, Jew'smallow, lettuce, Chinese cabbage, and cabbage;

root vegetables such as Japanese radish, lotus root, turnip, onion,burdock, Japanese ginger, sugar beet, carrot, shallot, and Japanesehorseradish;

fruit vegetables such as pumpkin, gourd, cucumber, and eggplant

fruits such as apple, loquat, peach, Japanese persimmon, and grape;

citrus fruits such as tangerine, kumquat, lemon, and kabosu;

melons such as watermelon, Oriental melon, and melon;

liverwort such as lichens, mosses, and liverworts;

seaweeds such as kelp and hijiki;

Good results are obtained when not just one but several kinds of theseare mixed together with the above described food and consumed raw.

In the health food of the present invention, cereals, millet, pulsesetc. may be consumed as is, but for those who are unaccustomed, may bepowdered and dispersed in water for consumption. When these cereals areheated, vitamin and enzyme are broken down, protein is denatured, andfat is oxidized, and degraded into glucose in the small intestine andabsorbed into the body, causing weight gain.

When the cereals, etc. are consumed in a sprouted state or at around thetime of sprouting, the degradation cycle of sprouted brown rice in thebody is as shown in FIG. 1. Starch, hemicellulose etc. are turned intofrom hexose to pyruvic acid, degraded by enteric bacteria in the largeintestine, and become nutritional component of the body.

Fermentation and degradation are carried out by enzyme and bacteria inthe large intestine, degrade fat into short-chain fatty acid. Regardingthis process, according to the theory by Mitsuo Kouda, it is said thatit will be as shown in FIG. 1.

The flow of the short-chain fatty acid is as follows. Starch, cellulose,and hemicellulose of the cereals etc. are turned into hexose andpentose, then via pyruvic acid into short-chain fatty acid includingacetic acid, butyric acid, propionic acid, and valeric acid, which areused for growth of enteric bacteria flora. These are absorbed in thelarge intestine and become energy. Indole and skatole are excreted instool. On the other hand, hydrogen, methane, and carbon dioxide gasesproduced are excreted but are partly absorbed into the blood andexhaled. As such, when it is turned into short-chain fatty acids, energyis produced within the body and the body becomes greatly enduring.

The health food of the present invention is preferably consumed to 80%or 60% fullness. When consumed on an empty stomach, peristaltic movementwithin the intestine is activated and motilin, a digestive hormone, issecreted as a hormone to excrete the content of the intestine when thestomach is empty. Peristaltic movement of the intestine becomes active,and occurrence of cancer is significantly reduced by facilitating theexcretion of the content of the intestine and stercoral.

According to the health food of the present invention, blood sugar leveland amount of insulin generally tend to rise in the body after eatingcooked rice. Blood sugar level tend to decrease over time by eating thehealth food of the present invention comprising brown rice (stercoral inparticular is dissolved).

As such, even in diabetes patients, increase in blood sugar level doesnot occur following ingestion of the health food of the presentinvention.

Generally, when millets are heated, steamed, or cooked, beta-starch isconverted into alpha-starch and absorbed in the small intestine.

However, meals from these are absorbed in the large intestine to make asubject healthy. Beta-starch is not degraded in the small intestine, butis degraded by digestive fluid in the large intestine, and fermented anddegraded by bacteria in the intestine. The fermentation and degradationis presumed to be by short-chain fatty acid cycle described below.

The health food of the present invention cannot be cultivated byproduction in conventional soil. In other words, in ordinary soil,residual nitrogen cycle as shown in FIG. 1 is carried out, and istherefore unsuitable.

On the other hand, the soil for cultivating the health food of thepresent invention has the components as shown in Table 3, resulting indecrease by half of residual nitrogen content.

Residual Residual nitrogen nitrogen Komatsuna Purchased at a 150 mgCultivated in the  75 mg supermarket soil of the present inventionSpinach Purchased at a 750 mg Cultivated in the 300 mg supermarket soilof the present invention Shirona Purchased at a 750 mg Cultivated in the300 mg supermarket soil of the present invention

The method for measuring the amount of residual nitrogen was as follows.

Five grams of leaves are ground, 145 cc of distilled water was added,and stirred well. This was filtered through filter paper, and test paperwas soaked in the filtrate obtained. After 1 second, it was measured ina measuring device. The calculated value was multiplied by 3 to obtainthe amount of residual nitrogen in 100 g.

Fertilizers conventionally used were not appropriate for plants such ascereals, and in the pursuit of savouriness, cereals harmful to the bodyare produced. In particular, alpha-starch was ingested due to processingtreatment such as heating and boiling in water.

In addition, with respect to the fertilizer used, agricultural chemical,antibiotic, and compound aiming to exterminate damages by disease andpest have harmful effects on the human body, causing bodies to benonresistant to diseases.

The soil for cultivating the health food of the present invention is asoil where conditions as shown in Table 3 are maintained. In particular,it is more preferred that it is closer to the central value.

In other words, it is a soil in which residual amount of agriculturalchemicals including insecticide, bactericide, and antibiotic orinorganic synthetic materials such as synthetic food, syntheticadditive, and chemical fertilizer is small, essentially a soil in whichthere is no residual amount, a soil in which fungi, microorganisms, andinsects can coexist with the food chain, and a soil in which organicfertilizer that does not use e.g. the above described agriculturalchemicals is added.

Millets that do not sprout produce by chemical fertilizer andagricultural chemical have broken DNA, highly acidic and highlyautoimmune plant which is a dead material has high concentration ofamino acids, and results in a plant resistant to pests.

For an organic fertilizer, it is more effective to mix photosyntheticbacteria into the soil. By the addition of photosynthetic bacteria,proliferation of filamentous bacteria which is a pathogen of ricecultivation etc. is suppressed and Actinomyces is proliferated. TheActinomyces has the function to kill filamentous bacteria.

In the brown rice etc. used in the health food of the present invention,a more preferable brown rice can be produced by using plant activatingenzyme “Aquagen” (the registered trademark of Nihon Pack Co.). This“Aquagen” is a plant fermentation seasoning developed based on naturalmaterials. It is fermented with Aspergillus oryzae to bring forth theinnate ability of the plant for “further activation of photosynthesis”,so that the immunity of plant is increased, the concentration of aminoacids is increased, and innate flavor of the plant is brought forth.When immunity is increased, the plant becomes resistant to damages bydisease and pest, and regeneration of cells is reinforced, so that ifthe plant is eaten by bugs the same portion will regenerate.

Further, chitin goes through the plant cell wall to bind to specificprotein, delivered to nuclear DNA, synthesis of mRNA, RNA, and proteinon which dormant DNA acts increases, immunity is increased, chitinase issecreted to protect the cell when contacted by pathogens and pests, andimmunocyte prevents invasion from the outside.

In addition, when it is converted into DNA, the substance for immunestrength is ingested from the plant, so the insects can share, as wellas the plant changes itself into where virus does not enter.Accordingly, a suitable plant can be cultivated without usingconventional agricultural chemical or chemical fertilizer.

In this way, photosynthesis of plant is enhanced and increase in yieldof high quality plant is expected.

Cereals such as rice and wheat and millets used for the health food ofthe present invention are cultivated in soil containing highconcentrations of amino acid. When chitosan is applied to soil duringgrowth of these plants, resistance against pests is increased, andregeneration efficiency is also good.

Moreover, the water applied to soil is preferably strong electrolyzedwater. The strong electrolyzed water is superior in bactericidal effect.The strong electrolyzed water is produced by adding sodium chloride orpotassium to water, electrolyzing the aqueous sodium chloride, andcollecting electrolyzed strong acidic water from the anodic electrodeside and at the same time strong alkaline water is produced at thecathode side.

The strong electrolyzed water includes strong acidic water of pH 3 orless (substantially 2.7 or less) and strong alkaline water of pH 11.5(substantially 12 or more), and these strong electrolyzed waters are nota replacement of agricultural chemical as bactericide. They are more orless a preventive agent, and are not effective when disease hasdeveloped.

Rice culture regions of the world have a temperature of above a certaindegree. The regions have temperature of 36° C. in 3 months or more andhave high precipitation. The absorption of water of plants in thisregion is approximately 70%, which is adapted to water content of humanbody 70%. On the other hand, wheat culture regions such as Europe havetemperature and precipitation inferior to rice culture regions, and itis said that water content of plants in the wheat culture regions is30%. The plants of the regions are adapted to these natural phenomena.Accordingly, humans adapt to plants and resulted in the present foodculture. In addition, when the necessary water does not exist,photosynthesis cannot be carried out and satisfactory food does notgrow. This results in decrease in immune strength and vulnerability topests.

Advantages of the Invention

According to the health food of the present invention, because cereals,millets etc. are consumed raw so it is easy to consume, and they can bepowdered and consumed raw for easy consumption and easy digestion, sothat they can be easily served. In addition, powder of the cereals etc.can be dispersed in water for consumption as juice or soup.

By consuming it raw, it is fermented and degraded enteric bacteria inthe large intestine, and then absorbed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a short-chain fatty acid cycle in the body;

FIG. 2 shows a cycle of residual nitrogen ingested from vegetables etc.

FIG. 3 shows a comparison of aldose reductase (AR) inhibitory activityin samples.

BEST MODE FOR CARRYING OUT THE INVENTION

The health food of the present invention will now be described.

The cereals, millets, pulses, tubers, leaf vegetables, fruit vegetables,citrus fruits, melons, fruits, rosette crops, root vegetables, seaweeds,seeds or liverwort used in the health food of the present invention arecultivated in a soil in which residual amount of agricultural chemicalsincluding insecticide, bactericide, and antibiotic or inorganicsynthetic materials such as synthetic food, synthetic additive, andchemical fertilizer is small, essentially a soil in which there is noresidual amount, a soil in which fungi, microorganisms, and insects cancoexist with the food chain, using organic fertilizer that does not usee.g. the above described agricultural chemicals.

In particular, soil used for cultivating the cereals, millets, pulses,tubers, leaf vegetables, fruit vegetables, citrus fruits, melons,fruits, rosette crops, root vegetables, liverwort, seaweeds or seeds ofthe health food of the present invention is preferably a soil in whichnaturally occurring leaf mold is the main component. Cereals etc. grownin such soil contain starch etc. different from those of conventionalstarch, which is superior in degradation of sugar within the body.

Because starch contained in cereals, millets, and pulses without heatprocessing etc. is beta-starch, it is degraded by enteric bacteria inthe large intestine, turned into short-chain fatty acid such as butyricacid and valeric acid, absorbed and becomes a source of energy.

Sprouted brown rice of AKITAKOMACHI cultivated in such a soil wascompared with sprouted brown rice by conventional method in measurementof degree of growth. Results are shown in Table 1 below.

Table 1 shows that AKITAKOMACHI from conventional soil had 21 unsproutedgrains even after 72 hours in rice incubator (water temperature 32° C.).

On the other hand, in the case of HITOMEBORE rice from the soilcomponent shown in Table 3 of the present invention, there were nograins which did not sprout after 72 hours in the same rice incubator(water temperature 32° C.). In other words, all of the brown ricesprouted.

TABLE 1-1 {circle around (1)} Produced in2003/Kakizaki/AKITAKOMACHI/rice incubator (sprouted at water temperature32° C.) Allowed Allowed Allowed to Allowed to Kakizaki to sprout for 0Kakizaki to sprout for 24 Kakizaki sprout for Kakizaki sprout for 2003AKITAKOMACHI hour AKITAKOMACHI hours AKITAKOMACHI 48 hours AKITAKOMACHI72 hours Number Thickness Width Length Thickness Width Length ThicknessWidth Length Thickness Width Length of Grains (mm) (mm) (mm) (mm) (mm)(mm) (mm) (mm) (mm) (mm) (mm) (mm) 1 2.04 2.84 5.14 2.21 2.82 5.38Maximum Maximum Maximum Maximum Maximum Maximum 2 2.12 2.78 4.90 2.252.86 5.39 2.18 2.86 6.40 2.12 3.31 5.61 3 2.04 2.73 5.02 2.29 2.48 5.322.24 2.92 5.75 2.30 3.15 6.50 4 2.00 2.76 5.11 2.20 2.98 5.08 2.22 2.975.81 2.16 2.95 5.85 5 1.89 2.36 4.89 2.10 2.79 5.16 2.22 2.91 5.65 2.382.85 6.65 6 2.16 2.59 5.06 2.30 2.24 5.35 2.19 3.37 5.58 2.24 3.00 5.307 2.04 2.71 5.06 2.23 2.20 5.02 2.15 3.27 5.63 2.21 2.96 5.54 8 1.952.69 4.77 2.80 2.77 5.14 2.10 3.07 5.62 2.18 3.00 5.27 9 1.98 2.82 5.072.24 3.05 4.87 2.15 2.95 5.10 2.30 3.30 6.10 10 2.17 2.78 5.09 2.18 2.885.72 2.30 3.13 5.89 2.15 3.11 5.43 11 1.93 2.83 5.09 2.38 2.84 5.54 2.202.90 5.67 2.17 2.97 12 2.17 2.85 5.10 2.10 2.72 5.33 13 1.98 2.65 5.062.33 2.58 4.51 14 2.09 2.73 5.36 2.13 2.79 5.43 15 2.10 2.87 5.12 2.203.26 5.35 16 1.98 2.78 5.02 2.41 2.85 5.32 17 2.04 2.72 5.11 2.16 2.605.39 Minimum Minimum Minimum Minimum Minimum Minimum 18 2.13 2.66 5.262.19 2.30 5.80 2.17 2.71 5.02 2.08 2.88 4.74 19 2.15 2.37 5.64 2.08 3.105.24 2.16 2.57 5.34 2.30 2.53 5.23 20 2.17 2.89 5.82 2.41 3.00 5.64 2.062.45 5.57 2.19 2.72 4.90 21 1.94 2.73 4.83 2.27 2.63 5.16 2.15 2.72 5.392.07 3.05 5.45 22 1.95 2.75 4.84 2.24 3.12 5.26 2.10 2.83 5.10 2.07 2.475.85 23 1.93 2.78 4.88 2.32 2.95 5.34 2.23 2.90 5.27 2.10 2.89 5.45 242.07 2.70 4.79 2.28 2.65 5.31 1.96 2.71 5.29 2.30 2.21 4.95 25 2.16 2.674.93 2.18 2.80 5.29 2.30 3.07 5.17 2.03 2.65 4.91 26 2.15 2.59 4.91 2.432.93 4.96 2.34 2.73 5.51 2.04 2.49 5.24 27 1.99 2.87 4.96 2.22 2.66 5.542.08 2.69 5.42 2.27 2.81 5.37 28 2.05 2.85 5.12 2.09 3.00 5.73 29 1.932.74 4.94 2.30 2.86 5.18 30 2.07 2.90 5.07 2.22 2.82 5.29 AverageAverage Average Average Average Average 31 2.02 2.58 4.99 2.25 3.07 5.322.18 2.89 5.51 2.18 2.87 5.50 32 2.09 2.71 5.27 2.14 2.95 5.23 33 2.072.70 4.79 2.39 3.10 5.21 Weight (110 Sprouted Not Weight (110 SproutedNot grains) sprouted grains) sprouted 34 2.05 2.75 5.38 2.15 3.02 5.242.4 g 70 grains 40 grains 2.5 g 89 grains 21 grains 35 2.20 2.74 4.822.21 3.05 5.04 1 grain 1 grain 36 2.10 2.46 5.33 2.22 2.81 5.25 0.0220.023 37 1.98 2.93 5.00 2.14 2.81 5.11 38 1.93 2.90 4.87 2.27 2.90 5.2939 2.11 2.75 5.05 2.37 2.98 5.64 40 1.99 2.71 5.02 2.50 2.35 5.78 412.05 2.59 4.81 2.43 2.91 5.07 42 1.97 2.57 4.87 1.84 2.96 5.24 43 2.012.61 4.75 2.10 3.04 5.35 44 1.99 2.61 5.11 2.40 2.75 4.74 45 2.10 2.684.81 2.35 3.07 5.54 46 2.01 2.72 5.17 2.30 3.12 5.61 47 1.98 2.81 5.262.22 2.77 5.26 48 2.06 2.80 5.16 2.17 2.89 5.41 49 2.02 2.65 4.94 2.202.92 5.56 50 1.96 2.81 4.69 2.53 3.39 5.50 51 2.17 2.80 5.03 2.57 3.055.30 52 2.11 2.64 5.23 2.31 2.99 5.53 53 1.96 2.70 5.50 2.32 2.93 5.2854 2.02 2.96 5.09 2.32 2.84 5.53 55 2.02 2.76 5.20 2.35 2.90 5.38 562.11 2.41 5.04 2.50 2.95 5.54

TABLE 1-2 {circle around (1)} Produced in 2003/Sasaki/HITOMEBORE/riceincubator (sprouted in water temperature 32° C.) Allowed to Allowed toSasaki sprout for 0 Sasaki sprout for 2003 HITOMEBORE hour HITOMEBORE 24hours Number Thickness Width Length Thickness Width Length of Grains(mm) (mm) (mm) (mm) (mm) (mm)  1 2.12 2.23 5.30 Maximum Maximum Maximum 2 2.15 2.81 5.22 2.28 3.27 6.23  3 2.22 2.61 4.80 2.25 3.05 6.03  42.28 2.78 5.02 2.30 3.25 6.02  5 2.06 2.78 4.93 2.31 2.95 6.03  6 2.112.98 5.20 2.32 3.10 5.91  7 2.23 2.84 4.99 2.31 3.18 6.05  8 2.27 2.864.80 2.33 3.10 6.14  9 2.20 2.84 5.14 2.29 3.07 5.53 10 2.03 2.74 4.902.32 2.95 6.70 11 2.07 2.89 5.05 2.35 3.03 6.14 12 2.10 2.95 4.62 132.12 2.89 4.86 14 2.15 2.75 5.53 15 2.04 2.63 5.02 16 2.20 2.62 4.85 172.15 2.94 5.14 Minimum Minimum Minimum 18 1.92 2.54 4.98 2.10 2.90 5.2319 2.08 2.56 5.49 2.27 2.88 5.40 20 2.08 2.99 4.65 2.26 3.12 4.98 212.03 2.71 5.23 2.19 3.13 4.98 22 2.20 2.93 5.25 2.04 3.02 5.12 23 1.982.93 5.11 2.28 3.11 4.70 24 2.03 2.69 5.52 2.10 3.15 5.32 25 1.98 2.935.28 2.30 2.97 4.90 26 2.12 2.52 4.92 2.03 3.00 4.87 27 2.04 2.98 5.532.20 2.88 4.88 28 2.10 3.31 5.11 29 1.95 2.81 4.71 30 1.99 2.64 5.02Average Average Average 31 2.16 2.83 5.04 2.24 3.06 5.56 32 1.86 2.975.08 33 1.93 2.88 5.11 Weight (110 Sprouted Not grains) sprouted 34 2.232.78 5.32 2.85 100 grains 10 grains 35 2.04 2.87 4.91 1 grain 36 2.002.64 5.09 0.026 37 2.20 2.71 4.71 38 2.14 2.79 4.98 39 2.15 2.88 5.12 402.25 2.84 4.65 41 2.11 2.96 5.13 42 2.31 2.81 4.93 43 2.19 2.81 5.28 442.08 2.80 4.65 45 2.06 2.42 4.92 46 2.02 2.75 4.96 47 1.97 2.72 5.11 482.18 3.05 5.23 49 2.14 3.09 5.07 50 2.18 2.71 5.02 51 2.05 3.01 4.82 522.09 2.32 5.31 53 2.10 2.59 4.86 54 2.04 2.86 4.67 55 2.05 2.74 4.81 562.15 2.88 5.19 Allowed to Allowed to Sasaki sprout for Sasaki sprout for2003 HITOMEBORE 48 hours HITOMEBORE 72 hours Number Thickness WidthLength Thickness Width Length of Grains (mm) (mm) (mm) (mm) (mm) (mm)  1Maximum Maximum Maximum Maximum Maximum Maximum  2 2.28 3.00 5.58 2.302.86 6.28  3 2.31 3.21 5.85 2.34 3.15 6.00  4 2.23 2.02 5.65 2.35 3.105.65  5 2.28 3.10 6.19 2.36 2.90 6.20  6 2.32 3.24 6.35 2.35 2.80 5.79 7 2.34 3.35 5.81 2.33 2.90 5.75  8 2.29 3.10 5.91 2.21 3.25 5.41  92.27 2.92 6.02 2.25 3.35 6.38 10 2.29 3.10 6.03 2.28 3.04 6.00 11 2.353.15 5.75 2.29 3.20 6.04 12 13 14 15 16 17 Minimum Minimum MinimumMinimum Minimum Minimum 18 2.29 3.20 5.60 2.29 2.85 4.98 19 2.29 3.295.27 2.29 2.80 5.53 20 2.05 2.90 4.70 2.05 2.65 5.95 21 2.04 2.70 5.562.04 2.86 4.75 22 2.40 2.95 5.43 2.40 2.47 6.45 23 2.15 2.94 4.82 2.152.64 5.42 24 2.18 3.01 5.39 2.18 2.72 5.39 25 2.36 3.02 5.06 2.36 2.975.43 26 2.18 2.80 5.19 2.18 2.92 5.32 27 2.27 2.43 5.71 2.27 2.93 4.9828 29 30 Average Average Average Average Average Average 31 2.26 2.975.59 2.26 2.92 5.69 32 33 Weight (110 Sprouted Not Weight (110 SproutedNot grains) sprouted grains) sprouted 34 2.9 g 105 grains 5 grains 3 g110 grains 0 grains 35 1 grain 1 grain 36 0.264 0.027 37 38 39 40 41 4243 44 45 46 47 48 49 50 51 52 53 54 55 56

As shown in Tables 1-1 and 1-2, as compared to cultivation inconventional soil, it is apparent that rice resistant to disease iscultivated in the soil for cultivating the health food of the presentinvention.

Additionally, results of analysis of components of common white rice,sprouted brown rice, and sprouted brown rice from the soil of thepresent invention (by Japan Food Research Laboratories) are shown below.

TABLE 2 Content in the sprouted brown Content in Article rice of thecommon sprouted Content in analyzed Present Invention brown rice whiterice Iron 1.64 mg/100 g 1.56 mg/100 1.15 mg/100 g Calcium 15.6 mg/10017.7 mg/100 8.1 mg/100 Potassium 163 mg/100 135 mg/100 11.2 mg/100Magnesium 137 mg/100 132 mg/100 12.5 mg/100 Zinc 1.91 mg/100 2.06 mg/1001.23 mg/100 Inositol 211 mg/100 212 mg/100 12 mg/100 Dietary Fiber 2.8g/100 2.7 g/100 0.5 g/100 Phytic Acid 840 mg/100 831 mg/100 n.d.(mesoinosit hexaphosphate) Free Gamma- 13 mg/100 24 mg/100 n.d. AminoAcid Total Ferulic 24 mg/100 23 mg/100 5.4 mg/100 Acid Note: Methods ofmeasurement Iron: o-phenanthroline absorption spectrometry, Calcium: ICPspectrometry, Potassium, magnesium, and zinc: atomic absorptionspectrometry, Inositol: bioassay Dietary fiber: enzyme-weight assay,Phytic acid: vanadomolybdic acid absorption spectrometry Freegamma-aminobutyric acid: amino acid automatic analysis Total ferulicacid: high performance liquid chromatography

Effects that cannot be expected from conventional soil are achieved bythe soil for cultivating the cereals etc. of the health food of thepresent invention.

The range of appropriate level of components of the nutrients of thissoil (100 g of soil) is as follows.

TABLE 3 Article analyzed Appropriate range Acidity (pH) 3.2~5.5~7.5Electroconductivity 0.02~0.05~5 Nitrogen Nitrogen content of amino acids(A-N) 0.02~0.3~50 mg (N-N) 0.02~0.7~70 mg Phosphate in available form2~15~400 mg Exchangeable potassium 1~15~300 mg Absorbance index ofphosphate 40~500~3000 mg Exchangeable lime (Calcium) 50~200-1000 mgExchangeable magnesia (Magnesium) 5~35~400 mg Manganese in availableform 0.5~5~70 PPM Iron in available form 1.5~15~300 PPM Copper inavailable form 0.1~1~30 PPM Zinc in available form 1.5~10~80 PPM Boron0.5~2~30 PPM Molybdenum 0.002~0.05~2 PPM Humus 1.0~9.0% Capacity of basesubstitution 5~40 CDC

By cultivating the cereals etc. of the present invention in soilcontaining the components shown in Table 3, health food can be ingested.

In the leaves of cereals cultivated in the soil of the presentinvention, 300 mg or less of residual nitrogen was normal.

However, when cultivated in soil using inorganic chemical fertilizer andagricultural chemical of the conventional method, spinach had residualnitrogen of 800 to 1600 mg.

Because residual nitrogen is said to have harmful effects on the humanbody, the less is the better. Residual nitrogen in plant leavestransforms into nitrate, turns into nitrite (a carcinogen) in the humanmouth, and turns into nitrosamine (a carcinogen) in the stomach. Whenthe nitrosamine is absorbed into the blood, it turns into metheloglobin,binds to erythrocytes, and disables delivery of oxygen. This causessuppression of insulin production and causes the subject to besusceptible to diabetes. When delivery of oxygen by erythrocytes isdecreased, the subject becomes oxygen-deprived. Children will havepurple lips.

The method of measuring the amount of residual nitrogen was as follows.

Five grams of leaves are ground, and 145 cc of distilled water wasadded. This was filtered through filter paper, and test paper was soakedin the filtrate for 1 second. The number obtained as measured bychromatography was multiplied by 3 to obtain the amount of residualnitrogen in 100 g.

To describe about sprouted brown rice among the cereals of the presentinvention, by cultivating in the soil described above, amino acid basedon nucleic acids of natural organic matter is reinforced due tophotosynthesis by sunlight, dormant enzyme is activated, gamma-aminoacid (GABA) is accumulated in the sprouted portion, and activeingredient of brown rice increases, so that it contains moretai-nutrient than unsprouted brown rice. GABA is known to activate theblood stream and to have a function to facilitate metabolism.

Uncooked brown rice etc. may be consumed by powdering by a blender, or 1to 4 grains per consumption may be consumed each meal. When the subjectis accustomed to meals as grains, it may be gradually increased to 1meal of uncooked brown rice per day.

Example 1

Increase in blood sugar level when consuming cooked rice consisting ofbrown rice and uncooked brown rice and cooked rice of conventional whiterice were measured.

As a comparative example, blood sugar level and insulin was measuredafter consumption of 100 grams of white rice, brown rice, and uncookedbrown rice at 10 A.M. on an empty stomach. The results of changesmeasured after several tens of minutes were as follows.

TABLE 4 Before 30 minutes 60 minutes 90 minutes 120 minutes Time Mealpost meal post meal post meal post meal White rice Blood sugar level(mg/100 g) 103.1 137.3 142.8 140.6 129.3 Insulin (μU/ml) 4.3 17.8 22.424.7 23.5 Brown rice Blood sugar level (mg/100 g) 101.6 138.1 152.6139.4 120.6 Insulin (μU/ml) 4.6 22 22.5 23.1 18.4 Uncooked brown riceBlood sugar level (mg/100 g) 97.8 121 126 115.5 107.4 Insulin (μU/ml)4.1 12.5 12.1 11.1 9.1

As is seen, decrease in blood sugar level was seen with uncooked brownrice.

According to this, Increase in blood sugar level and significantincrease in insulin were hardly seen with uncooked brown rice.

Example 2

One hundred grams of uncooked sprouted brown rice was powdered in ablender, consumed as is, or is consumed by seasoning with salt.

Example 3

In cultivation of food such as the brown rice used in the health food ofthe present invention, a comparative experiment between a cultivation insoil using conventional chemical fertilizer or organic fertilizer and acultivation in soil using the above described Aquagen seed (theregistered trademark of Nihon Pack Co.) was carried out.

Case 1

In soil applied with chemical fertilizer or agricultural chemicalnecessary for ordinary plants, approximately 65 rice plants/3.31 m² wereplanted, and cultivated using temporary disease and pest control.

Due to dense planting, photosynthesis was insufficient and irregularrice was prone to be produced. As a result, a well-balanced meal wasnecessary when consuming this rice.

Case 2

In a soil having high quality with high concentration of amino acids,amount of organic fertilizer necessary for plant growth using Aquagenseed, and for cultivation without agricultural chemicals, approximately30 to 40 plants/3.31 m² were planted. Photosynthesis became active,irregular rice were less prone to be produced, and the plants were moreresistant to damages by disease and pest. Lactic acid bacteria etc.including aerobic microzyme (bacteria, Actinomyces, yeast, andfilamentous bacteria) in soil are generated, the amount of yeastincreased, higher alcohols were produced, low molecular nutrients wereabsorbed, and amino acid concentration increased. Plants with residualnitrogen of 300 mg or less were cultivated.

Case 3

Samples of malted rice (koji) were produced by adding “strengthenunrefined-soy-sauce (moromi)” as a seed bacterium into the followingcrops.

Ratio of extraction (V/W) Rokkaku-reishi mushroom 12 Ancient Black Rice6 Rice according to the present invention 6

These samples of malted rice (koji) were fermented in separate culturevessels and an experiment in prevention activity of malted rice (koji)to diabetic complications, such as diabetic retinitis, diabeticnepfritis or neurosis, was made. A ratio of aldose reductase (AR)inhibitory activity was measured as an index showing preventionactivity.

The four extraction solvents below were prepared for the samples.

-   -   A: phosphate buffer solution    -   B: ethanol    -   C: methanol    -   D: phosphate buffer solution processed in boiling bath for five        minutes

Table 5 shows AR inhibitory activity of each sample measured using theseextraction solvents.

The ratio of inhibitory activity (%)=[1−(A0−A1)/(C0−C1)]×100

-   -   (wherein, A0: absorbance of sample before enzyme reaction, A1:        absorbance of sample after enzyme reaction, C0: absorbance of        control before enzyme reaction, C1: absorbance of control after        enzyme reaction)

These data have shown that AR inhibitory activity of Rokkaku-reishimushroom in ethanol solvent was high since the extraction densitythereof was twice. However, those in other solvents were not high. Onthe other hand, AR inhibitory activity of the rice (Aquagen rice)cultivated in the soil according to the present invention was very highas compared with other samples. Especially, a remarkable effect of ARinhibitory activity in phosphate buffer solution was identified.

Further, “An experiment in an anti-cancer effect of aldose reductase(AR)” was made.

The samples were left in water twenty-four hours and steamed for fortyminutes at 110° C. After the samples were fermented withunrefined-soy-sauce (moromi)” as a seed bacterium for forty-five hours,they were dried and preserved at low temperature. These preservedsamples were diluted with phosphate buffer solution (potassiumphosphate) into twice or fifth times and kept in refrigerator at 4° C.

After separating enzyme using a filter, samples were passed through adialysis membrane to obtain small-sized molecular.

Since protein can be passed through an ionization membrane, proteinhaving molecular weight of 500-1000 was obtained.

α-A G-A A-P ACP Aquagen rice (the present invenmtion) 1941 207 1003415647 Ancient Black Rice 286 28 4161 4088 Mushroom 364 20 422 770 α-A:quantity of alpha-amylase (for liquefaction)(cutting off starch) G-A:quantity of glucoamylase (for saccharification) A-P: quantity of acidityprotease (decomposing amino acid protein) ACP: quantity of aciditycarboxypeptitase (sizing down amino acid)

The experiment shows that Aquagen rice cultivated in soil according tothe present invention contains many enzymes in quantity.

INDUSTRIAL APPLICABILITY

The health food of the present invention does not require heat andelectricity costs, does not undergo processing treatment of cereals,millets etc., and is trouble-free because it is consumed raw. When it isdifficult to consume raw, it can be easily consumed by powdering it andmixing it together with water as juice or soup.

1-48. (canceled)
 49. A soil, comprising, per 100 g of the soil, 0.02 to50 mg of amino acid nitrogen, denoted by “A-N”, 0.02 to 70 mg of anitrogen content in one chemical form different from the amino acidform, denoted by “N—N”, 2 to 400 mg of phosphate in available form, 1 to300 mg of exchangeable potassium, 50 to 1000 mg of exchangeable lime, 5to 400 mg of exchangeable magnesia, 0.5 to 70 ppm of availablemanganese, 1.5 to 300 ppm of available iron, 0.1 to 30 ppm of availablecopper, 1.5 to 80 ppm of available zinc, 0.5 to 30 ppm of boron, 0.002to 2 ppm of molybdenum, and 1.0 to 9.0% of humus, and wherein the soilhas an absorbance index of phosphate of 40 to 3000 mg, a capacity ofbase substitution of 5 to 40 CEC, an acidity of 3.2 to 7.5 in pH, and anelectric conductivity of 0.02 to 5, denoted by “mS/cm”.
 50. The soilaccording to claim 49, further comprising a naturally occurring leafmold.
 51. The soil according to claim 49, wherein fungi, microorganismsor insects can coexist with a food chain in the soil, and wherein thesoil further comprises an organic fertilizer.
 52. The soil according toclaim 49, wherein the soil comprises, per 100 g of the soil, 0.3 mg ofA-N, 0.7 mg of N—N, 15 mg of phosphate in available form, 15 mg ofexchangeable potassium, 200 mg of exchangeable lime, 35 mg ofexchangeable magnesia, 5 ppm of available manganese, 15 ppm of availableiron, 1 ppm of available copper, 10 ppm of available zinc, 2 ppm ofboron, 0.05 ppm of molybdenum, and wherein the soil has an absorbanceindex of phosphate of 500 mg, an acidity of 5.5 in pH, and an electricconductivity of 0.05 mS/cm.
 53. A method for cultivating aresidual-nitrogen-reduced crop comprising growing the crop in the soilaccording to claim
 49. 54. The method according to claim 53, wherein thecrop is selected from the group consisting of rice with or without husk,cereals with or without husk, millets with or without husk, pulses withor without husk, tubers, leaf vegetables, fruit vegetables, citrusfruits, melons, fruits and root vegetables.
 55. The method according toclaim 53, wherein the crop is subjected to at least one treatmentselected from the group consisting of radiation of far infrared rays,dispersion of powders of tourmaline, magnesium or chitosan, anddispersion of mature fermented organic matter.
 56. The method accordingto claim 53, wherein the crop is subjected to at least one treatmentselected from the group consisting of sterilization by ultraviolet rays,reinforcement of vitamin D by ultraviolet ray, irradiation, pressuretreatment by oxygen pressure or nitrogen pressure, temperature treatmentby storing in soil or water of 5 to 10 degrees Celsius, heat conductiontreatment to a degree that cells of the crop are not destructed,bactericidal treatment, fermentation treatment, biotreatment, solidtreatment, fluid treatment, gas treatment, and supercritical treatment.57. A method for cultivating a residual-nitrogen-reduced crop comprisinggrowing the crop in the soil according to claim
 52. 58. The methodaccording to claim 57, wherein the crop is selected from the groupconsisting of rice with or without husk, cereals with or without husk,millets with or without husk, pulses with or without husk, tubers, leafvegetables, fruit vegetables, citrus fruits, melons, fruits and rootvegetables.
 59. The method according to claim 57, wherein the crop issubjected to at least one treatment selected from the group consistingof radiation of far infrared rays, dispersion of powders of tourmaline,magnesium or chitosan, and dispersion of mature fermented organicmatter.
 60. The method according to claim 57, wherein the crop issubjected to at least one treatment selected from the group consistingof sterilization by ultraviolet rays, reinforcement of vitamin D byultraviolet ray, irradiation, pressure treatment by oxygen pressure ornitrogen pressure, temperature treatment by storing in soil or water of5 to 10 degrees Celsius, heat conduction treatment to a degree thatcells of the crop are not destructed, bactericidal treatment,fermentation treatment, biotreatment, solid treatment, fluid treatment,gas treatment, and supercritical treatment.
 61. A method for treatingdiabetes comprising administering an effective amount of aresidual-nitrogen-reduced crop grown in the soil according to claim 49to a patient in need thereof.
 62. A method for treating diabetescomprising administering an effective amount of aresidual-nitrogen-reduced crop grown in the soil according to claim 52to a patient in need thereof.
 63. A method for treating cancercomprising administering an effective amount of aresidual-nitrogen-reduced crop grown in the soil according to claim 49to a patient in need thereof.
 64. A method for treating cancercomprising administering an effective amount of aresidual-nitrogen-reduced crop grown in the soil according to claim 52to a patient in need thereof.